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Query: UNIPROT:P51532 (
transcriptional activator
)
6,546
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The biological response to progesterone is mediated by two distinct forms of the human progesterone receptor (
hPR
-A and
hPR
-B). In most cell contexts,
hPR
-B functions as a
transcriptional activator
of progesterone-responsive genes, whereas
hPR
-A functions as a transcriptional inhibitor of all steroid hormone receptors. We have created mutations within the carboxyl terminus of
hPR
which differentially effect the transcriptional activity of
hPR
-B in a cell- and promoter-specific manner. Analogous mutations, when introduced into
hPR
-A, have no effect on its ability to inhibit the transcriptional activity of other steroid hormone receptors. The observed differences in the structural requirements for
hPR
-B and
hPR
-A function suggest that transcriptional activation and repression by PR are mediated by two separate pathways within the cell. In support of this hypothesis, we have shown that
hPR
-A mediated repression of human estrogen receptor (hER) transcriptional activity is not dependent on hER expression level but depends largely on the absolute expression level of
hPR
-A. Thus, it appears that
hPR
-A inhibits hER transcriptional activity as a consequence of a noncompetitive interaction of
hPR
-A with either distinct cellular targets or different contact sites on the same target. We propose that
hPR
-A expression facilitates a ligand-dependent cross-talk among sex steroid receptor signaling pathways within the cell. It is likely, therefore, that alterations in the expression level of
hPR
-A or its cellular target can have profound effects on the physiological or pharmacological responses to sex steroid hormone receptor ligands.
...
PMID:The A and B isoforms of the human progesterone receptor operate through distinct signaling pathways within target cells. 796 70
In humans, the biological response to progesterone is mediated by two distinct forms of the progesterone receptor (human (h) PR-A, 94 kDa and
hPR
-B, 114 kDa). These two isoforms are transcribed from distinct estrogen-inducible promoters within a single copy PR gene; the only difference between them is that the first 164 amino acids of
hPR
-B (B-upstream sequence) are absent in
hPR
-A. In most cell lines such as MCF-7 (human breast cancer cells), CV-1 (monkey kidney fibroblasts), and HeLa (human cervical carcinoma cells),
hPR
-A functions as a transcriptional repressor, whereas
hPR
-B functions as a
transcriptional activator
of progesterone-responsive genes. Interestingly, in these cell contexts,
hPR
-A also acts as a trans-dominant repressor of the transcriptional activity of other steroid hormone receptors. In contrast to
hPR
-A, which functions predominantly as a ligand-dependent transcriptional repressor, we show in this study that the A isoform of the chicken PR (cPR-A) lacks this trans-dominant repressor function and is a
transcriptional activator
in all contexts examined. By constructing chimeras between the N-terminal domains of the chicken and human PR, we mapped the trans-dominant repressor function of
hPR
-A to the first 140 amino acids of the protein. Notably, when this 140-amino acid "repressor" domain is placed onto chicken PR-A, the activity of the latter changes from a
transcriptional activator
to a repressor. Interestingly, however, this "repressor domain" is necessary, but not sufficient, for trans-repression as it is inactive when it is tethered to a heterologous protein. This suggests that the trans-repression function is comprised not only of the repressor domain of
hPR
-A but also requires the context of the receptor to function. The identification of a discrete inhibitory region within
hPR
-A which is transferable to another receptor implies that this region interacts with a set of transcription factors or adaptors that are distinct from those recognized by
hPR
-B, the identification of which will be required to define the mechanism by which
hPR
-A modulates steroid hormone receptor transcriptional activity. Thus, although chickens and humans both produce two very similar forms of the progesterone receptor, it is clear from these studies that the mechanism of action of progesterone in these two systems is quite different.
...
PMID:Mapping and characterization of the functional domains responsible for the differential activity of the A and B isoforms of the human progesterone receptor. 940 67
In humans, the biological response to progesterone is mediated by two forms of the progesterone receptor (
hPR
-A; 94kDa and
hPR
-B; 114kDa). These two isoforms are transcribed from distinct, estrogen-inducible promoters within a single-copy progesterone receptor (PR) gene; the only difference between them is that the first 164 amino acids of
hPR
-B are absent in
hPR
-A. In most cell lines,
hPR
-A functions as a transcriptional repressor of progesterone-responsive promoters, whereas
hPR
-B functions as a
transcriptional activator
of the same genes. The observation, made in the early 1990s, that shorter isoforms of some transcriptional activators can act as transrepressors of the transcriptional activity of the larger isoforms, initiated a line of investigation that led to the discovery that
hPR
-A is a strong transrepressor of
hPR
-B activity. Interestingly,
hPR
-A also functions as a transdominant repressor of the transcriptional activity of the estrogen, glucocorticoid, androgen, and mineralocorticoid receptors. A specific inhibitory domain (ID) within
hPR
-A responsible for this activity has been mapped to the extreme amino terminus of the receptor. Interestingly, although this inhibitory domain is contained within both PR isoforms, its activity is manifest only in the context of
hPR
-A. The identification of a discrete inhibitory region within
hPR
-A, whose activity was masked in the context of
hPR
-B, suggests that these two receptor isoforms may interact with different proteins (transcription factors, co-activators, co-repressors) within the cell. In support of this hypothesis, we have recently observed that the co-repressor SMRT (silencing mediator of retinoid and thyroid receptors) interacts much more tightly with
hPR
-A than with
hPR
-B. This important finding led to the initial conclusion that the ability of
hPR
-A to repress
hPR
-B transcriptional activity could occur as a consequence of
hPR
-B/A heterodimerization, where the presence of SMRT in the complex could prevent transcriptional activation. The observation, however, that
hPR
-A also inhibits human estrogen receptor (hER) transcriptional activity, a receptor with which
hPR
-A is not able to heterodimerize, suggests that there must be additional complexity. This chapter outlines what is known about the mechanism of action of
hPR
-A and
hPR
-B and how this knowledge has enhanced our understanding of PR pharmacology.
...
PMID:The A and B isoforms of the human progesterone receptor: two functionally different transcription factors encoded by a single gene. 1054 81
The human progesterone receptor (PR) exists as two functionally distinct isoforms, hPRA and hPRB. hPRB functions as a
transcriptional activator
in most cell and promoter contexts, while hPRA is transcriptionally inactive and functions as a strong ligand-dependent transdominant repressor of steroid hormone receptor transcriptional activity. Although the precise mechanism of hPRA-mediated transrepression is not fully understood, an inhibitory domain (ID) within human PR, which is necessary for transrepression by hPRA, has been identified. Interestingly, although ID is present within both
hPR
isoforms, it is functionally active only in the context of hPRA, suggesting that the two receptors adopt distinct conformations within the cell which allow hPRA to interact with a set of cofactors that are different from those recognized by hPRB. In support of this hypothesis, we identified, using phage display technology, hPRA-selective peptides which differentially modulate hPRA and hPRB transcriptional activity. Furthermore, using a combination of in vitro and in vivo methodologies, we demonstrate that the two receptors exhibit different cofactor interactions. Specifically, it was determined that hPRA has a higher affinity for the corepressor SMRT than hPRB and that this interaction is facilitated by ID. Interestingly, inhibition of SMRT activity, by either a dominant negative mutant (C'SMRT) or histone deacetylase inhibitors, reverses hPRA-mediated transrepression but does not convert hPRA to a
transcriptional activator
. Together, these data indicate that the ability of hPRA to transrepress steroid hormone receptor transcriptional activity and its inability to activate progesterone-responsive promoters occur by distinct mechanisms. To this effect, we observed that hPRA, unlike hPRB, was unable to efficiently recruit the transcriptional coactivators GRIP1 and SRC-1 upon agonist binding. Thus, although both receptors contain sequences within their ligand-binding domains known to be required for coactivator binding, the ability of PR to interact with cofactors in a productive manner is regulated by sequences contained within the amino terminus of the receptors. We propose, therefore, that hPRA is transcriptionally inactive due to its inability to efficiently recruit coactivators. Furthermore, our experiments indicate that hPRA interacts efficiently with the corepressor SMRT and that this activity permits it to function as a transdominant repressor.
...
PMID:The opposing transcriptional activities of the two isoforms of the human progesterone receptor are due to differential cofactor binding. 1075 95
